Direct Measurements of Electric Fields in Weak OH···π Hydrogen

Sep 21, 2011 - Hydrogen bonds and aromatic interactions are of widespread importance in chemistry, biology, and materials science. Electrostatics play...
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Direct Measurements of Electric Fields in Weak OH 3 3 3 π Hydrogen Bonds Miguel Saggu,* Nicholas M. Levinson,* and Steven G. Boxer* Department of Chemistry, Stanford University, Stanford, California 94305-5080, United States

bS Supporting Information ABSTRACT: Hydrogen bonds and aromatic interactions are of widespread importance in chemistry, biology, and materials science. Electrostatics play a fundamental role in these interactions, but the magnitude of the electric fields that support them has not been quantified experimentally. Phenol forms a weak hydrogen bond complex with the π-cloud of benzene, and we used this as a model system to study the role of electric fields in weak OH 3 3 3 π hydrogen bonds. The effects of complex formation on the vibrational frequency of the phenol OH or OD stretches were measured in a series of benzene-based aromatic solvents. Large shifts are observed and these can be converted into electric fields via the measured vibrational Stark effect. A comparison of the measured fields with quantum chemical calculations demonstrates that calculations performed in the gas phase are surprisingly effective at capturing the electrostatics observed in solution. The results provide quantitative measurements of the magnitude of electric fields and electrostatic binding energies in these interactions and suggest that electrostatics dominate them. The combination of vibrational Stark effect (VSE) measurements of electric fields and highlevel quantum chemistry calculations is a general strategy for quantifying and characterizing the origins of intermolecular interactions.

’ INTRODUCTION Hydrogen bonding is of fundamental importance for structure, function, and dynamics in a vast number of chemical and biological systems.1 6 In conventional hydrogen bonds, X H 3 3 3 A, a hydrogen atom bridges the proton donor X and proton acceptor A. The donor is usually very electronegative, for example, O or N, whereas the acceptor is an electronegative atom with at least one lone pair of electrons. Hydrogen bonds vary enormously in bond energy from ∼15 40 kcal/mol for the strongest interactions to less than 4 kcal/mol for the weakest. It is proposed, largely based on calculations, that strong hydrogen bonds have more covalent character, whereas electrostatics are more important for weak hydrogen bonds, but the precise contribution of electrostatics to hydrogen bonding is widely debated.2 In this work, we consider a class of hydrogen bonds that are important in noncovalent aromatic interactions,2,7 where πelectrons play the role of the proton acceptor, which are a very common phenomenon in chemistry and biology.8,9 They play an important role in the structures of proteins and DNA, as well as in drug receptor binding and catalysis.10,11 For example, edge-toface interactions between the partially positively charged hydrogen of one aromatic system and the partially negative π-cloud of another aromatic system contribute to the stereoselectivity of organic reactions and to self-assembly in crystals of benzene and are widespread in proteins.9,12,13 Another important class of these interactions is the cation π interaction, where cations, such as the charged side chains of arginines and lysines, interact with the π-cloud of an aromatic system such as tyrosine, phenylalanine, and tryptophan. These interactions are ubiquitous in proteins and are believed to be important for their structures,10 but as yet no experimental measurements of electric r 2011 American Chemical Society

fields have been made to determine the extent to which these interactions are dictated by classical electrostatics as opposed to other effects (e.g., van der Waals, charge-transfer, etc.). Here we present the first experimental measurements of the magnitude of electric fields in aromatic edge-to-face interactions using a model system consisting of phenol and a series of substituted benzene derivatives. We used the OH (or OD) stretch modes of phenol as vibrational probes of the change in electric field upon complex formation, where shifts in the IR spectra are directly related to electric field changes through the vibrational Stark effect. We chose this system based on the elegant studies of Fayer and co-workers on hydrogen bond exchange dynamics for phenol and benzene, which form an edge-to-face (or OH 3 3 3 π hydrogen bonding) complex in solution.14 The structure of this complex has been studied by DFT calculations in the gas phase and by MD simulations in solution.14,15 The calculations suggest that the hydroxyl group of phenol is pointing toward the center of one C C bond of the benzene ring and interacts with the favorable electrostatic potential of the benzene π-system in a weak OH 3 3 3 π hydrogen bond (strength